The determination of trace anions in concentrated phosphoric acid
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1 TECHNICAL NOTE The determination of trace anions in concentrated phosphoric acid Authors Edward Kaiser and Jeffrey Rohrer Thermo Fisher Scientific, Sunnyvale, CA, USA Keywords Ion chromatography, IC, IonPac ICE-AS; IonPac AS-HC; ionexclusion pre-separation, ICE Introduction The determination of trace anions in phosphoric acid is hampered by a large excess of phosphate ion. Chloride determination at. mg/l (ppm) in 8% (w/w) phosphoric acid represents a concentration ratio of : (chloride to phosphate). Diluting the concentrated sample overcomes the problem of a large concentration of the interfering matrix ion, but lacks the required sensitivity for the contaminant ions of interest. An improved method for determining trace anions in concentrated phosphoric acid has been developed to overcome this problem., Trace inorganic anions are separated from the high concentration of phosphate by an ion-exclusion separation prior to an ion-exchange separation. This Technical Note describes the theory, set up, and analytical procedure for the determination of chloride, nitrate, and sulfate at sub-mg/l (ppm) levels in 8% (w/w) phosphoric acid. Summary of the method A Thermo Scientific Dionex IonPac ICE-AS ion-exclusion column is used to separate the analyte ions from an excess of phosphate matrix ions. A selected fraction from the ion-exclusion separation is cut and sent to a mm Thermo Scientific Dionex IonPac AS-HC anion-exchange concentrator column. The concentrated ions are then eluted onto a mm AS-HC column set, where the anions of interest are separated and detected by suppressed conductivity.
2 Experimental Equipment Thermo Scientific Dionex DX- Ion Chromatography system* consisting of: GP Gradient Pump, microbore configuration CD Conductivity Detector with a temperature controlled conductivity cell (DS) LC Enclosure with Rheodyne valves, PEEK, rear loading * Equivalent or improved results can be achieved using the Thermo Scientific Dionex ICS- + HPIC system. Thermo Scientific Dionex Dionex RP- single piston pump Pressurizable Reservoir Chamber (Three) L Plastic bottle assemblies, for external water and for rinse solution (P/N 9) O-ring, Teflon encapsulated, for rinse solution bottle (P/N ) O-rings Teflon encapsulated, for Reservoir Chamber (P/N 7 for O-ring) Air pressure gauge, 7 kpa ( psi) (for external water) cm ( in.) of green PEEK tubing, diameter of.7 mm (. in.), to connect columns and make a μl sample loop Teflon bottles as sample containers (VWR, P/N 7- or Thermo Scientific Nalgene, P/N - for ml narrow mouth bottles) Thermo Scientific Dionex PeakNet Chromatography Workstation s AG-HC guard column, mm (P/N 9) AS-HC analytical column, mm (P/N 9) AG-HC concentrator column, mm (P/N 9) AG as trap column, mm (P/N 9) ICE-AS analytical column, 9 mm (P/N 79798) Thermo Scientific Dionex Anion Self-Regenerating Suppressor (ASRS ), mm (Replaced by Thermo Scientific Dionex AERS ( mm), P/N 8) Reagents and standards Deionized water (DI H O), Type I reagent grade, 7.8MΩ cm resistance or better Sodium hydroxide, % (w/w) aqueous solution (Fisher Scientific) Thermo Scientific Dionex Chloride standard, mg/l, ml (P/N 79) Thermo Scientific Dionex Sulfate standard, mg/l, ml (P/N 7) Nitrate standard, mg/l, ml (Ultra Scientific, VWR, P/N ULICC-) Conditions Ion Exclusion : ICE-AS Trap : AG, mm Eluent: Deionized water Flow Rate:. ml/min Ion Chromatography Analytical : AS-HC, mm Guard : AG-HC, mm Concentrator : AG-HC, mm Eluent: mm sodium hydroxide, step to mm sodium hydroxide Flow Rate:.8 ml/min Volume: μl Detection: Suppressed conductivity, Dionex ASRS, AutoSuppression external water mode Suppressor Current Setting: ma Expected System Backpressure:. MPa ( psi) (with concentrator column in line) Expected Background Conductivity: μs
3 Preparation of solutions and reagents Eluent Solutions mm Sodium hydroxide (IC eluent) Dilute. g of % (w/w) sodium hydroxide with degassed, deionized water (having a specific resistance of 7.8 MΩ cm or greater) to a final weight of, g in the eluent bottle. Avoid the introduction of carbon dioxide from air. To minimize dilution of the concentrated acid sample, it is recommended that small aqueous aliquots be used for the method of standard addition. Each of these additions will have a consistent volume while the concentration for the anions of interest varies. A convenient sample size for spiked standards in 8% phosphoric acid is ml ( g) with a. ml aqueous spike. This represents a dilution of.% (. ml spike/ ml sample =.% dilution). mm Sodium hydroxide (IC eluent and Dionex IonPac AG trap column regeneration) Dilute. g of % (w/w) sodium hydroxide with degassed, deionized water (having a specific resistance of 7.8 MΩ cm or greater) to a final weight of, g in the eluent bottle. Avoid the introduction of carbon dioxide from air. To minimize introducing contamination through sample handling, the concentrated acid can be dispensed directly into the sample container, by weight, on a top-loading balance. Table illustrates how aqueous standards are diluted and prepared. The following formula can be used to calculate concentrations in mg/l for dilutions: Standard solutions Stock standard solution (, mg/l) Use Thermo Scientific Dionex or commercially available, mg/l ion standard solution. Working standard solution ( mg/l) To prepare a mixed working standard solution, combine. ml of each anion stock solution with deionized water and dilute to a final volume of, ml. Calibration Prepare calibration standards at a minimum of three concentration levels by diluting the working standard. Select a range similar to the expected concentrations in the samples. The method of standard addition (adding one or more increments of a standard solution to sample aliquots of the same size) can be used to minimize the effect of the concentrated acid matrix on the measured conductivity of the analytes of interest. (Conc. of stock solution, mg/l) * (Vol. of stock solution, ml) = (Conc. of dilute standard, mg/l) * (Vol. of dilute standard, ml) Dionex Ionpac AG trap column regeneration The AG column must first be regenerated. Monitoring the blank will indicate when regeneration is necessary. Typically, monthly regeneration is necessary, but it will depend on the quality of the deionized water and usage rate of the instrument. Increased contamination in the water blank indicates that the AG needs to be regenerated. The procedure is as follows:. Pump mm sodium hydroxide through the Dionex IonPac AG column at. ml/min for minutes.. Follow with a rinse of deionized water at the same flow rate for minutes. Table. Method of standard additions for concentrated phosphoric acid. Concentration of stock standard (mg/l) Amount of stock to make a ml final volume of working standard in deionized water (ml) Concentration of working standard (mg/l) Concentration of ml 8% phosphoric acid when μl of working standard is added (mg/l) Chloride,.. Sulfate,.,. Nitrate,..
4 Discussion of method This method addresses the challenge of determining trace concentrations of contaminant ions such as nitrate, chloride, and sulfate in a matrix composed of a high concentration of phosphate ion. This is accomplished in two steps: an ion-exclusion (ICE) pre-separation followed by injection of a portion of the ICE separation to an ion chromatographic (IC) separation., : ICE-AS Trap : AG, mm Eluent: Deionized water Flow Rate:. ml/min Volume: μl Detection: Conductivity Peaks:. Nitrate/Chloride/Sulfate. Phosphate The ion-exclusion mechanism separates ionized species from nonionized or weakly ionized species. This occurs because of a negatively charged hydration shell on the stationary phase surface called the Donnan membrane. Figure illustrates the application of the ICE mechanism to the separation of 8% concentrated phosphoric acid that was injected onto a ICE-AS ionexclusion column. This chromatogram is a measurement of the unsuppressed conductivity response for the ICE separation. The strong acid ions, such as nitrate, chloride, and sulfate, are excluded and elute as a small peak at minutes. The weakly ionized phosphate matrix ions are retained and elute as a large peak. This separation is not applicable to dilute phosphoric acid samples because dilute phosphoric acid is partially ionized. A series of schematics (Figures ) illustrates the operation of the chromatography hardware. The concentrated phosphoric acid sample is loaded via a pressurized reservoir into the μl sample loop To 8 Figure. Ion exclusion separation of trace anions in 8% phosphoric acid.chlorate, bromate, oxalate, phosphate, nitrite, and nitrate. sample out of the sample container into the sample loop at a flow rate of. ml/min ( ml/hr). This technique ensures that a representative sample of the concentrated phosphoric acid sample is loaded into the sample loop. It is important to pass at least loop volumes through the sample loop to ensure reproducible sampling. While the minute IC separation is taking place, approximately ml of sample will have been pushed through the sample loop with the pressurized reservoir. To To Concentrator RP- DI H O AG Trap GP Eluent In Loop In ICE-A& ICE-AS Concentrator AG-HC, mm Injection Analytical s AG-HC AS-HC mm Figure. Loading the sample loop.
5 The concentrated phosphoric acid sample is then delivered with the high-purity water carrier stream to the ICE-AS. A AG is placed after the Dionex RP- pump to act as an anion trap column for the deionized water. Any contaminants present in this water will impact the quality of the blank. The first portion of the ICE separation from. to 7. minutes is sent to waste (Figure ). Then, the concentrator column is placed in-line with the ICE column and the portion from 7. to. minutes is captured on the concentrator column (Figure ). After. minutes the -mm AG-HC concentrator column is placed in-line with the mm AS-HC analytical column set and the concentrated ions are separated (Figure ). This time window should ensure the concentration of all the nitrate, chloride, and sulfate with minimal concentration of phosphate. RP- DI H O AG Trap GP Eluent In Loop In ICE-A& ICE-AS Concentrator AG-HC, mm Injection Analytical s AG-HC AS-HC mm Figure. First portion of the ICE separation (time. 7. min). RP- DI H O AG Trap GP Eluent In Loop In ICE-AS AG-HC, mm Concentrator Figure. Concentrating the cut portion from the ICE separation (time 7.. min). Load Injection Analytical s AG-HC AS-HC mm
6 RP- DI H O AG Trap GP Eluent In Loop In ICE-AS Analytical s AG-HC AS-HC mm AG-HC, mm Concentrator Inj. Injection Figure. Separating the retained ions. The IC separation utilizes the AS-HC column with an isocratic eluent of mm sodium hydroxide. The high capacity of the AS-HC column allows injection of these relatively concentrated samples without overloading. Figure shows a separation of the common anions with the mm AS-HC column under standard conditions. The attractive feature of this separation is that phosphate elutes last. A -mm microbore column was chosen because it has a -fold increase in mass sensitivity over the standard bore column. This facilitates faster loop loading because : AS-HC, mm Peaks:. Fluoride mg/l (ppm) Eluent: mm Sodium hydroxide. Chloride Temperature: C. Nitrite Flow Rate:. ml/min. Sulfate Inj. Volume: μl. Bromide Detection: Suppressed conductivity,. Nitrate AutoSuppression mode 7. Phosphate 8 Figure. Isocratic separation of the common anions. 7 smaller sample amounts are required. The microbore format also offers low eluent consumption as well as less waste generation. A AG-HC ion exchange column was used as the concentrator column in the mm format instead of mm because the mm column had four times more capacity than the mm column and lower back pressure at the microbore flow rate. No significant degradation in separation efficiency was observed when coupling a mm concentrator column with a mm analytical column set. For this method the AS-HC column standard conditions were modified. The eluent strength was reduced from mm to mm sodium hydroxide to optimize the separation of the trace anions from the excess of phosphate matrix ions. The method was run at ambient temperature. During the IC separation, the pressurized vessel is filling the sample loop for the next analysis. The deionized water rinses the ICE-AS column and associated tubing to ensure there is no contamination from the previous sample. After the phosphate has eluted from the column, the eluent concentration is stepped from to mm sodium hydroxide for minutes. This ensures that the column is rinsed of residual phosphate. The method returns the system to equilibrate at mm sodium hydroxide for the next injection. If this cleanup step is not used, phosphate will continue to build up on the analytical column and cause a gradual decrease in retention time for phosphate and the other analytes.
7 System preparation and test Refer to the system configuration schematics in Figures and Table, which summarize the types and lengths of tubing required for system configuration. The chromatography hardware is divided into two parts: the ion-exclusion pretreatment portion with the Dionex IonPac ICE-AS column and the IC analysis portion with the AS-HC column. IC system. Prepare the Dionex ASRS supressor by following the Quickstart instructions (Dionex Document 8-) included with the Instructions and Troubleshooting Guide for the ASRS.. Install the mm AG-HC and AS- HC column set by using the red. mm (. in.) tubing. To minimize dead volume, use the smallest possible lengths of tubing and ensure that the ends of the tubing are smooth and level.. Construct a μl sample loop by cutting a 9.9 cm (.9 in.) portion of the black. mm (. in.) PEEK tubing.. Install this loop in place of the mm AG-HC concentrator column between ports and of the injection valve in the IC analysis system.. Install the Dionex ASRS supressor and configure it in the external water mode as described in the SRS manual.. Establish eluent flow through the mm AG-HC and AS-HC analytical column set. The expected background conductivity is μs. (Note: For trace analysis, it will take at least hours for the system to achieve a stable background conductivity.) 7. Verify proper operation of the IC portion of the system by injecting a low-level ppm standard to replicate the column test chromatogram. 8. Remove the μl sample loop and install the mm AG-HC concentrator column. Make sure that the arrow indicating flow on the column is pointed from port to port and that the tubing length connecting the outlet of this column and port is as short as possible. 9. Configure the IC valve so that the mm AG-HC concentrator column is in-line with the mm AG-HC and AS-HC analytical column set. Check for leaks. The expected system backpressure for these three columns at.8 ml/min is ~, psi (. MPa). Ion-exclusion sample pretreatment system This section describes the preparation of the pretreatment portion of the system. It is important that the same type and length of tubing as described in Table be used to successfully perform this analysis. Changes in tubing length will result in a different cut from the ICE-AS column being delivered to the AS-HC concentrator column. Table. Details of tubing configuration for trace anions in phosphoric acid. Connection Points Tubing Description Length (cm) Remarks ICE exit to Port Green.7 mm (. in.) ICE input to Port Green.7 mm (. in.) 7 Port to Port Green.7 mm (. in.) -μl sample loop -mm AG-HC to Port Red. mm (. in.) Should be as short as possible -mm AG-HC to Port Black. mm (. in.) Port to analytical column Red. mm (. in.) Should be as short as possible 7
8 . Cut a cm (7 in.) portion of the.7 mm (. in.) PEEK green tubing to make a μl sample loop and install this loop between port and of the sample valve.. Prepare the AG trap column according to the directions in the section titled AG Trap Regeneration. (Caution: Before the AG is installed in the system, it is important that the sodium hydroxide solution used for storage or cleaning be completely rinsed away. The ICE-AS column is not compatible with sodium hydroxide eluents.). The entire pathway from the Dionex RP- pump to port of the IC valve is plumbed with the.7 mm (. in.) PEEK green tubing. Install the Dionex IonPac AG column at the exit port of the Dionex RP- pump.. Install the ICE-AS column using a 7 cm piece of green tubing between the exit of the ICE-AS column and port of the injection valve. Use a cm portion of green PEEK tubing between port of the sample valve and the input of the ICE-AS column.. Check to see that there is about. kpa ( psi) of head pressure on the incoming deionized water that feeds the Dionex RP- pump.. Connect the exit port of the reagent reservoir to port of the sample valve with the.7 mm (. in.) green tubing. 7. Configure a waste line from port of the sample valve with the green tubing. 8. Connect the reagent reservoir to helium pressure of about. KPa ( psi). 9. Begin with a container filled with deionized water as a sample to rinse the sample lines of any trace contamination.. Set a flow rate of. ±. ml/min for the Dionex RP- pump by adjusting the dial on the pump. This should be measured with the mm AG-HC concentrator column out of line. Measure the flow rate by collecting the waste coming out of port of the IC valve. It is critical for the success of this method that the flow rate be consistent.. Pump deionized water at. ml/min through the ICE-AS column to waste without the mm AG-HC cloumn in line for hour. This will remove the. mm heptafluorobutyric acid storage solution. Sulfate is usually found in the blank. Typical initial blank sulfate values will be ~ μg/l.. The ICE-AS coilumn can be further conditioned by rinsing it with mm phosphoric acid for hours at. ml/min followed by a -hour rinse with 7.8 MΩ cm deionized water. This will reduce the sulfate blank to μg/l or less. Continue to monitor the blank, especially when starting up the system after it has been idle for more than two days. 8
9 System operation After all aspects of the instrumentation have been prepared, the system is ready for analysis.. Load the PeakNet method shown in Table.. Fill the μl sample loop with deionized water. Use helium gas pressure to push the deionized water sample using the reagent reservoir (Figure ).. Analyze a blank by loading deionized water as the sample. It may take several runs until the system has been rinsed of contamination.. After an acceptable blank has been established, the system is ready for analysis.. Exercise caution when handling concentrated phosphoric acid. Consult the applicable Material Safety Data Sheet (MSDS) for specific details about protective equipment, reactivity, storage, disposal, and health effects.. Concentrated phosphoric acid, 8% (w/w), can be loaded directly into the μl loop by the reagent delivery module. At this concentration the phosphoric acid is viscous and moves slowly to fill the sample loop. Ensure that the loop has had enough sample pass through by collecting the liquid that exits port of the sample pretreatment valve. A good practice is to load at least loop volumes. The method is set up so that the reagent reservoir pushes sample into the sample loop during the IC separation. With a pressure of. KPa ( psi), ml of concentrated phosphoric acid will have been passed through the sample loop in minutes. 7. Ensure that the Dionex RP- pump is consistently delivering. ±. ml/min. Figure 7 illustrates what happens when the flow rate is faster or slower. At the slower flow rate, not enough of the sample is cut from the ICE separation, resulting in incomplete recovery of the anions of interest. At the faster flow rate, too much of the ICE separation is cut, resulting in the phosphate peak almost obscuring the analytes of interest. 8. Other factors will also affect the quality and consistency of the ICE preseparation. Changing the cut time window specified in the method (7. to. minutes) will impact the amount of analyte and matrix ions that are delivered to the concentrator column. Varying the sample volume will also affect the character of the ICE separation. For example, doubling the sample volume from to μl increases the sensitivity for trace determinations. Method development will be needed to ascertain the impact of any changes from the specified method. Table. PeakNet method for the analysis of concentrated phosphoric acid. Total Time (min) A = Inject B = Load ICE Time (min) IC Time (min) Injection %A mm NaOH %B mm NaOH Figure Comment Init Inject A Load the sample loop. Inject A 8.. Inject B Begin ICE separation. 7. Load B Send cut portion from ICE separation to AG-HC column, mm... Inject B Begin IC separation. Concentrator column in-line..9.9 Inject A.. Inject A Step to mm sodium hydroxide for cleaning. 9. Inject A End mm sodium hydroxide. 9. Inject A Equilibrate at mm sodium hydroxide.. Inject A 9
10 9. Quantifying the levels of anions in phosphoric acid is best accomplished by the method of standard additions. This involves adding one or more increments of a standard solution to sample aliquots of the same size (see the Calibration section). Results and discussion A representative blank is shown in Figure 8. It was found that after concentrated phosphoric acid had been in the sample loop pathway, several runs of deionized water were required to completely rinse away the high concentration of phosphate matrix ions. A blank was established after seven replicate runs yielded reproducible results. These levels, quantified based on a calibration curve for these ions in deionized water, are below the expected concentrations for high-purity grade concentrated phosphoric acid. The anion values, of this deionized water blank, were subtracted from the levels found in the concentrated phosphoric acid samples. A small amount of phosphate was detected in the blank, as carryover from previous injections. This will not significantly impact sample analysis. A chromatogram for the analysis of 8% (w/w) phosphoric acid is shown in Figure 9. The large phosphate matrix (peak ) is well separated from the anions of interest. Chloride determination was hampered by a dip before the peak. A feature in the PeakNet chromatography software called void treatment was utilized to reliably quantitate this peak. A detail of the chloride peak is shown in Figure. The peak that starts at 9 minutes is a result of the step to the higher eluent concentration. Any residual phosphate left in the column is eluted with this high eluent concentration. To verify proper quantification of analytes in the phosphoric acid matrix, increasing concentrations of chloride, nitrate, and sulfate were added into 8% phosphoric acid. Spikes of,, and μg/l of chloride;,, and, μg/l of nitrate; and,,, and μg/l of sulfate yielded coefficients of determination (r ) values greater than.99. Ion Exclusion : Trap : Eluent: Flow Rate: A B C ICE-AS AG, mm Deionized water A:. ml/min B:. ml/min C:. ml/min Ion Chromatography Analytical : AS-HC, mm Guard : Concetrator : AG-HC, mm AG-HC, mm Eluent: Flow Rate: Volume: μl Detection: Peaks: mm Sodium hydroxide step to mm Sodium hydroxide.8 ml/min Suppressed conductivity, Dionex ASRS-ULTRA, AutoSuppression external water mode. Unidentified. Unidentified. Phosphate Figure 7. Effect of ICE eluent flow rate on IC separation.
11 Ion Exclusion : Trap : Flow Rate: Volume: ICE-AS AG, mm Deionized water. ml/min Eluent: Flow Rate: Ion Chromatography Analytical : AS-HC, mm Guard : Concetrator : Eluent: AG-HC, mm AG-HC, mm mm Sodium hydroxide step to mm Sodium hydroxide.8 ml/min μl Detection: Suppressed conductivity, Dionex ASRS-ULTRA, AutoSuppression external water mode Peaks:. Chloride. μg/l. Unidentified -. Sulfate. Nitrate.. Phosphate - Ion Exclusion : Trap : Eluent: Flow Rate: Concetrator : ICE-AS AG, mm Deionized water. ml/min Ion Chromatography Analytical : AS-HC, mm Guard : AG-HC, mm AG-HC, mm Eluent: mm Sodium hydroxide step to mm Sodium hydroxide Flow Rate:.8 ml/min Volume: μl Detection: Suppressed conductivity, Dionex ASRS-ULTRA, AutoSuppression external water mode Peaks:. Chloride. μg/l Figure 8. Representative blank. Ion Exclusion (ICE) Pretreatment Peaks:. Chloride μg/l (ppb) : ICE-AS. Unidentified - ICE Eluent: Deionized water. Sulfate 7 ICE Flow Rate:. ml/min. Nitrate Volume: μl. Phosphate - : AG-HC, AS-HC, mm IC Eluent: mm Sodium hydroxide IC Flow Rate:.8 ml/min Detection: Suppressed conductivity, Dionex ASRS, AutoSuppression external water mode mm Sodium hydroxide clean up.. Figure. Detail of chloride peak. Based on this calibration curve, a spike of μg/l chloride,, μg/l sulfate, and μg/l nitrate yielded recoveries between 8 and %. These values are within the SEMI (Semiconductor Equipment and Materials International) recommended guidelines of 7 % recovery at % of the specified maximum limit of impurity. Table summarizes the spike/recovery data. To determine method precision, a sample of a highpurity grade 8% phosphoric acid was analyzed by this method. For n=7, a relative standard deviation (RSD) of less than % was obtained for μg/l chloride and 7 μg/l sulfate. Nitrate levels were determined to have an average concentration of μg/l with an RSD of %. At these low nitrate concentrations, partial coelutions of other analytes with nitrate cause a higher variability in the nitrate peak integration... Figure 9. Determination of trace anions in high purity 8% phosphoric acid.
12 Table. Spike recovery of trace anions in 8% phosphoric acid. Anion Phosphoric Acid Blank (μg/l ± SD)* * Corrected for system blank For n = 7 Spike (μg/l) Found- Blank (μg/l ± SD) Recovery (%) Chloride ±. ±. Sulfate 7 ±,, ± Nitrate ±. 8 ±. 8 Method detection limits (MDLs) were calculated using the standard deviation of seven replicate injections multiplied by the Student s t-value for the 99.% confidence level. MDLs for chloride, sulfate, and nitrate are in the low μg/l (ppb) range. The MDLs for this method are substantially below the maximum limit of impurity guidelines for phosphoric acid established by SEMI for the purest grade of phosphoric acid, as shown in Table. Table. Method detection limits and SEMI specifications for trace anions in high purity phosphoric acid. Anion Method Detection Limits (μg/l) SEMI C7.-9 Specification (μg/l) Chloride., Sulfate 8, Nitrate. Method Detection Limit = (SD) x (t s )99.% where (t s ) is for a single-sided Student s t-test distribution for n = 7. Precautions Exercise caution when handling concentrated phosphoric acid. Consult the Material Safety Data Sheet (MSDS) for more specific details about protective equipment, reactivity, and health effects. Use only the highest quality deionized water for the preparation of standards and eluents. Any ionic contamination present in the deionized water will adversely affect results. Teflon containers are recommended for holding the concentrated acid samples for delivery to the sample loop. Containers should be soaked for at least hours with 7.8 MΩ cm deionized water prior to use. It is good practice to dedicate all containers for trace analysis and keep them filled with deionized water when not in use. Method success depends on maintaining a consistent flow rate of deionized water from the Dionex RP- pump. Verify that the flow rate is. ±. ml/min. If the deionized water container feeding the Dionex RP- pump is not pressurized to at least. KPa ( psi), the pump may be prone to losing prime. Do not leave concentrated phosphoric acid in the sample loop and sample inlet lines for more than hours. The PEEK tubing can degrade after extended contact time with the concentrated acidic sample. References. Watanabe, K. Presented at the International Ion Chromatography Symposium, Dallas, TX, October 99; Poster.. Wu, M.; Chen, J. Micro. (), 997, 7.. Bader, M. J. Chem Educ. 7, 98, 7.. Weiss, J. Ion Chromatography, nd ed., VCH, Weinheim, Germany, 99, 9.. Troubleshooting Guide for HPLC Injection Problems. Rheodyne: Cotati, CA, 99.. SEMI International Standards: Semiconductor Equipment and Materials International, Mountain View, CA, Chemical/Reagents Volume, 997. Find out more at thermofisher.com/ic, 7 Thermo Fisher Scientific Inc. All rights reserved. All trademarks are the property of Thermo Fisher Scientific and its subsidiaries unless otherwise specified. Rheodyne is a registered trademark of IDEX Health & Science, LLC. Teflon is a registered trademark of The Chemours Co. FC LLC. This information is presented as an example of the capabilities of Thermo Fisher Scientific products. It is not intended to encourage use of these products in any manners that might infringe the intellectual property rights of others. Specifications, terms and pricing are subject to change. Not all products are available in all countries. Please consult your local sales representatives for details. TN77-EN 7S
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